Notes On Token Instrument And Double Line Sge Block Instrument(iriset)

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The use of token Block Instruments is permitted for controlling trains on a single line section. The object of providing such instruments is to prevent more than one train being in a block section at a time, and when the block section is clear, to admit one train into the section from either of the two ends, thus, guaranteeing absolute safety in the running of trains at all times, maintaining space interval between two trains. To achieve this a pair of Token Block Instruments, each containing a stipulated number of tokens (bearing serial number and code initials of the stations to which they apply), electrically interconnected are provided one at each end of the Block Section. The instruments are designed to have conscious co-operation of the two Station Masters at either end of the Block Section for electrically releasing a token from any one of them. This token is handed over to the driver of a train as an Authority to Proceed i.e., to leave the Block Station and enter the Block Section. Mechanism is provided to ensure that only one token can be released if none is extracted already from either instrument, and if once a token has been extracted, a second token cannot be extracted either from the same or the other instrument till such time the token already extracted is restored to either of them and the instrument set to normal and a fresh sequence of operations gone through. On a single line, where trains work under Absolute Block system, every train in its progress from one block station to the next shall be signalled over the block instruments. However, the signalling of trains, on block instrument, does not preclude the use of fixed signals,hand signals or the detonators whenever such signals may be necessary to protect obstruction on the line. Therefore, after receiving the token as the "authority to proceed", the driver must not proceed until all the necessary fixed or other signals have been exhibited. The driver must keep the token safely under his own charge and must give it to the Station Master or any other authorised person on arrival at the Block Station in advance, then this token shall be consigned into the block instrument for normalising the instruments at both ends of the Block Section. Neale's Block Instruments originally designed to issue "Card Permits" under the 'Line Clear' traffic system were later suitably modified as token Block Instruments. Since its inception, numerous modifications and improvements have been embodied, which render it reasonably reliable instrument for the safe working of trains on single line sections. In its latest form it is known as Neale’s Type 'A' Token Block Instrument. The earlier versions are known as Neale’s Voucher Block Instruments, and are classified as Type 'D', Type 'C' and Type 'B' instruments. Type 'B' instruments had been suitably converted to the working standards of Type 'A' instruments. IRS Drawings are now available for Neale’s Token Instruments. Neale’s Token Instruments are available in two versions:i) Neale’s Ball Token Instruments IRS Drg.No.SA 20701/M ii) Neale’s Tablet Token Instruments IRS Drg.No.SA 21701/M We shall first consider the Ball Token Instrument.

1

The tokens used in Neale’s Ball Token Instruments are hollow round steel balls. They have through groove cut on a diametric axis which have one of the following configurations:a) Round hole b) Rectangular hole c) Three sided (triangular) hole d) Four sided hole e) Five sided hole The different hole configurations viz., class A,B,C,D and E are as shown in Fig. 1.5.

1.5 NEALE’S BALL TOKEN HOLE CONFIGURATIONS (S20840-44)

2

Different hole configurations are provided to distinguish the token belonging to block instruments of different block sections. It ensures that a token belonging to the instrument of one block section cannot be inserted into an instrument belonging to an adjacent block section thus preventing wrong normalisation. Consecutive Block Sections shall be provided with tokens of configuration A,B and C. Following Block Sections shall be provided with similar configuration in the same order. Where a junction station falls in between or new crossing stations are opened tokens with special configuration and shall be provided. However, this arrangement shall not be required at the Junction Stations where tablet token instruments are provided for the other Section. The instrument has a capacity of 36 tokens to meet the traffic requirements. Normally 32 or less tokens only are used in a connected pair of instruments. There is also a device of notifying the Operator when all the tokens have been withdrawn from the instrument which happens under stress of unidirectional traffic. A maximum of 36 tokens are allotted for a pair of instruments of a Block Section so that the total number of tokens shall not exceed the maximum holding capacity of tokens of the instrument. A front view of the instrument is shown in figure 1.7 The instrument consists of the following important parts:1) SM's Lock 2) Top handle (Token Receiving Drum) 3) Bell Unit 4) Needle Indicator (Galvo) 5) Bottom (Operating) handle with token delivery drum. 6) Rack and Pinion 7) TCF and TGT locks with force dropping arrangement 8) Polarised Relay 9) Inter-stroke Interrupter (Jerking contact) 10) Commutator. 11) Contact arrangement 12) Tappet Rod (Plunger) 13) Safety Catch. 14) Token races with windows 15) Token Indicator 16) Token Selector 17) Last Stop Signal Control 18) Block Telephone

This provides a mechanical locking on the Block Instrument to prevent unauthorised operation in the absence of the Station Master. SM's Key when ‘Out’ will mechanically lock the bottom (Operating) Handle and Top Handle, thus preventing them from manipulation. Bottom handle can be locked in any of the three positions, whereas the Top Handle can only be locked in its position at 850 from the vertical. SM's Key when out will also disconnect the line battery and thus unauthorised bell codes cannot be sent to the other station. However, incoming bell codes are not affected.

3

Fig. 1.7 BALL TOKEN INSTRUMENT

4

It is a cylindrical cast iron drum with a recess to take one token. The recess opens at the top through an aperture in the drum housing normally covered by a hinged metal cap. In this position the arrow marked on the turning handle faces vertically upwards. A token is inserted into the instrument by placing it in this recess by lifting the hinged cap and then turning the handle anti-clockwise (by handle provided on the front) through approximately 1900. The recess is provided with a small fixture called the "Spigot". The shape of the spigot corresponds to the hole configuration on the tokens used in the Block Sections. The purpose of this spigot is to prevent insertion of a wrong class of token to clear the section. Two spring operated lock pawls are located one each at approximately 850 . and 1700. within the drum housing. These lock pawls normally press against the surface of the drum and do not, therefore, interfere with its movement if it is tuned with a token of correct dimensions in its recess. Should the drum be turned in the anti-clockwise direction with its recess partially or completely empty, the first lock pawl at 85 0 from the vertical position gets into the token recess and checks its further rotation. Should the first lock pawl fail to detect the presence of incorrect dimension of the object in the recess, the second lock pawl will check rotation beyond 1700. The token so consigned is led through a chute (which has no bottom) whose sides are carved sufficiently inwards to guide the token. The token enters the recess directly in the line closed position of the bottom handle. But in the other positions of the handle, it rests on the token receiving jaw. The chute ensures that foreign object (such as, bolts or nuts) inserted into the token receiver will not run down into the races but will fall right through to the bottom of the instrument. The top handle is provided with a lock, to lock it in the turned position between 75 0 to 850., by removing the SM's key. This arrangement prevents the insertion of the token in the absence of the Station Master on duty.

'It is used to communicate the prescribed code of bell signals. The bell is of single stroke type, the coil of which is wound to a resistance of 25 Ohms requiring a minimum operating current of 80 ma. It is worked in the local circuit in series with one of the two lock coils namely TCF and TGT through the contacts of the polarised relay operated by the line current.

This has an electromagnet coil wound to a resistance of 150 Ohms and requires a working current of 15-25 mA. The needle is attached at the front to an axle carrying a permanent magnet situated inside and between the coils and is free to move to either side as it is pivotted in its centre. It is mainly used to detect the presence of incoming and outgoing current. Besides, the deflection of the needle helps to indicate the position of the operating handle and the condition of the Block Section. The deflection due to outgoing current gives the position of the operating handle and the deflection due to incoming current that of the operating handle at the distant station instrument. An anti-clockwise deflection of the needle always indicates that the operating handle is in one of the two turned position namely, TCF or TGT. A clockwise deflection indicates that the operating handle is in the vertical or Line Closed position, except when a token is inserted into the instrument with the operating handle in either TCF or TGT position. In the latter case, the outgoing deflection changes to clockwise even with the handle turned indicating that there is no train in the Block Section. An incoming deflection in the clockwise direction indicates TCF lock is released in the instrument and that an anti-clockwise deflection indicates TGT lock is released.

5

The bottom handle is situated at the front middle bottom of the instrument. The Tappet Rod is threaded through the centre of the handle. The handle has three positions which indicate the condition of the Block Section as given below. (Ref. Fig. No.1.12/1). a)The handle with its arrow pointing vertical upward indicates ‘Line Closed’. This is the normal position. b) In the second position the arrow points to the right. This indicates that line clear for a certain train has been given. This is called the "Train Coming From" (TCF) position. c) In the third position the arrow pointed to the left. This indicates that line clear has been obtained and a token extracted. This position is called "Train Going To" (TGT). The token delivery drum forms an extension of the operating handle and is a heavy cast iron cylinder with a suitable recess in it to house one token. From this, the token is delivered when it comes out of the opening in the front when handle is turned to the TGT position. A toothed sector or pinion is mounted on the hexagonal extension at the end of the drum which works a rack below it every time the operating handle is turned. A rod connecting this sector to the spring clutch and the token selector causes both these to rotate along with the handle. The movement of the rack, when the operating handle is turned is prevented normally by two locking pawls engaging with notches cut in the rack as shown in Fig. 1.12/2. The movement of the handle from any particular position Line Closed, TCF or TGT is possible only when the proper locking pawl has been released from the notch in the rack, which can happen only through the co-operation of the distant station.

These lock coils are identical in every respect; but the units with armature cannot be interchanged. The coils are wound to a resistance of 28 Ohms each and require an operating current of 160 mA at a minimum working voltage of 4.5V. The armature of each, which is free to move has locking pawl carried on a spindle at one end. On each coil assembly is mounted a bent lever or the force dropping lever which is normally held up by the cams on the lock replacer (Ref.Fig. 1.13/1) disc mounted on to the rear end of the hexagonal extension of the operating handle. This limits the travel of the armature unless the bent lever falls forward which happens when the operating handle is pulled out of its slot withdrawing the cam projection from underneath the bent lever. When the lock coil is energised and the operating handle pulled out, the armature is attracted fully lifting with it the lock pawl out of the locking notch on the rack thus permitting the operating handle to be turned. The locking pawl is a small rectangular mild steel piece attached to a threaded spindle and secured to it by means of locking nut. Four operations are possible with the operating handle, viz., (1) Normal to TCF; (2) TCF to Normal, (3) Normalto TGT; and (4) TGT to Normal. Out of these four operations the TCF lock has to be energised for three operations (1) Normal to TCF, (2) TCF to Normal, and (3) TGT to Normal. The TGT lock coil has to be energised to enable the handle to be turned only to the TGT position.

6

Fig. 1.12/1 BALL TOKEN BOTTOM HANDLE ASSEMBLY 7

Fig. 1.12/2 REAR VIEW OF THE RACK AND PINION IN THE LINE CLOSED POSITION OF THE BOTTOM HANDLE The lock replacer disc has 4 conical projections or cams. Three of these are 'A', 'B' and 'C' as shown in figure and are of the same size and are so located that any two of them keep the two bent levers of the two locks (TCF) and (TGT) pushed up when the operating handle is in the normal or TCF position and the bent lever of the TCF lock coil alone in the TGT position of the operating handle. The bent levers force down the armatures and hence, the locking pawls into the locking notches in the rack. This helps to prevent sticking of the armature in the attracted position due to dirt, residual magnetism or any mechanical defect that would enable an unauthorised extraction of a token. Every time the operating handle is made to house in its slots after an operation the armatures of the lock coils are forced down thus ensuring safety. The fourth projection is longer than the three others so that even when the bottom handle is pulled forward, this does not release the bent lever. When the bottom handle is turned about one third from the line closed position towards TGT position where the handle cannot be housed in the pulled forward position it engages with the bent lever of the TGT lock and ensures force dropping of TGT lock in the check locking notch. This coincides with the time when the line current is momentarily interrupted by the interstroke interrupter. The TGT coils being de-energised, the armature and hence, the locking pawl is forced down on to the rack by the bent lever. If there is no current coming through again, the bottom handle would be prevented from being taken to the TGT position as the lock pawl which has forced down would lock the rack in the check lock position. The bottom handle can be turned further to TGT only when the TGT coil is energised again. This means that the operator at the distant station should still be keeping his tappet rod pressed sending a current on line. Thus a prolonged beat is necessary to take the bottom handle to the TGT position. This provides security against premature operation of the bottom handle to TGT position while receiving bell beat. The details of forced drop arrangement are shown in Fig.1.13/1. The combined details of Rack and Pinion, TCF, TGT locks with forced drop mechanism are shown in Fig.1.13/1.

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Fig.1.14 DETAILS OF FORCED - DROPPING MECHANISM 9

This is a three position relay which works on the line current. The movement of the contact spring depends on the polarity of the line current. The polarised relay of Specification No.S31/80 having a coil resistance of 77 Ohms is provided in all the instruments and it works on a rated current of 25 mA. The operation of the Neale's instrument, depends on the direction of the current received from the distant station. When the current is in a particular direction, the tongue of the polarised relay is attracted to one side completing the local circuit of single stroke bell and TCF lock coil. If it is in the opposite direction the tongue of the relay is attracted to the opposite side completing the local circuit of single stroke bell with TGT lock coil. When the direction of the incoming current is such as to release the TGT lock coil the bottom (operating) handle can be turned to TGT position and a token is delivered and releases the L.S.S. control, Electrically or Mechanically as provided. Polarised Relay confirming to S-31/80 alone shall be used in Block Circuits.

This relay with centre biased armature is for use in Railway Signalling circuits and for use with Single Line and Double Line Block Instruments in Electrified and Non-Electrified Sections.

Normal Position: The position of the armature when the relay is energised with the positive coil terminal R1 connected to the positive and R2 connected to the negative terminals of the battery. Reverse Position: The position of the armature when the relay is energised with the positive coil terminal R1 connected to the negative and R2 connected to the positive terminals of the battery. Pick up Value: The value of the current which is just sufficient to close normal or reverse contact of a relay under the specified conditions. Drop away Value: The value of the current at which the normal or reverse contact of a relay just opens under specified conditions. Arm: The moving part of the contact. Arm Contact: The moving contact which remains in between Normal and Reverse Contacts when the relay is deenergised. Normal Contact: The fixed contact on the left hand side of the relay when viewed from the front of the case, and which is closed when the armature is in the normal position. Reverse Contact: The fixed contact on the right hand side of the relay when viewed from the front of the case, and which is closed when the armature is in the reverse position. The terminals connected to the fixed contacts and the arm shall be identified by the letters as follows: N= Normal Contact R=Reverse Contact A=Arm Contact

10

To separate coils each of 38.5 Ω nominal resistance at 200C. The standard nominal resistance of the coils on assembly shall be obtained by connecting the two coil windings in series. When the armature is in vertical mid-position with the relay in the deenergised opposition, the contact clearance between the arm contact and any of the fixed contacts shall be not less than 1.5 mm. The contact clearance shall be equal on both sides.

Two contact pieces with a gap between the two are provided on a bakelite mounting on the spring clutch shaft (Fig.1.16). In the Line Closed Position of the bottom handle, the line circuit is made through by two finger springs resting on the bottom contact piece. When the bottom handle is turned, the clutch shaft is also rotated by a rod connected to the pinion on the bottom handle. Due to operation of operating/bottom handle, the contact springs moves over from the bottom contact piece to the top piece causing a momentary break in the line circuit. This causes a click in deflection of the needle indicators. This indicates to the Station Master at the current sending end that the operating handle is being turned at the distant station.

Fig. 1.16 At the station where line clear is obtained when the handle is being turned to TGT from Normal, the momentary break in the line circuit caused by this interstroke interrupter contact coincides with the time and TGT lock pawl is dropped by the lock replacer disc mounted on the rear part of the bottom handle. If current were not received continuously after the interrupter contact makes the line circuit again the lock pawl would lock the rack and hence the operating handle in the check lock position. To clear this locking notch the TGT lock coil should be energised again which thus necessitates the other end to give a prolonged beat to enable the handle being taken to the TGT position.

Four brass segments are mounted on an insulated curved bakelite segment threaded on the shaft carrying the spring clutch, with which the former engages by means of Jig Jaw teeth cut on the edge of the spring clutch. The shaft carrying the spring clutch is connected to a toothed sector pinion on the operating drum. Whenever the bottom handle is turned, this shaft rotates. 11

The commutator also moves along with the spring clutch shaft, thus changing the segments which comes into contact with springs connecting the battery line and earth. On the right side of the commutator is a jaw (token receiving jaw) for receiving a token from the token receiving drum when the handle is in TCF or TGT position. This prevents the token going right into the token recess of the instrument. When the plunger is pressed with a token resting on this jaw, a fork lever attached to the spring assembly shaft pushes the token into the instrument. This action revolves the commutator along disengaging the spring clutch shaft. Thus with every movement of the bottom handle, the commutator and spring clutch revolve as one unit, but when the plunger is pressed after inserting a token in either of the turned positions of the handle, the clutch disengages and allows the commutator to revolve independently reversing the polarity of the current transmitted in a subsequent operation of the plunger.

FIG.1.17 12

13

This consists of four finger springs mounted on an isolated lever below the commutator. The lever moves in an ARC through a connecting rod which moves whenever the plunger is pressed. This will result in the spring making contact with the segments mounted on the commutator. As seen from the back of the instrument battery terminals are connected to the first and third finger springs, earth to the second spring and line through Galvanometer to the fourth spring The commutator in line closed position of operating handle puts through spring 1,2 and 3,4 (Ref.Fig.No.1.17A and 1.26), when the plunger is pressed. When the bottom handle is turned to TCF or TGT position, the springs 1,4 and 2,3 are put through by the commutator, thus reversing the polarity of the applied voltage. The 4th spring of the contact making spring assembly is extended downwards and numbered as 5 to make the rest contact. This contact which is normally made when the plunger is not pressed, connects the line circuit to the polarised relay. But when the plunger is pressed the contact is broken and the polarised relay is isolated from the line circuit. Provision of Rest Contact fulfils the Special Requirement Vide SEM 17.144 that the Line Clear granting mechanism and Line Clear Receiving Mechanism shall not actuate at one and the same time.

This is a steel rod with an electroplated knob passing through the middle of the bottom handle. When pressed it operates the shaft connected to the contact making spring assembly. This causes the spring to make contact with the commutator segments for sending out a current on line. The polarity of the current depends on the position of the commutator.

The safety catch is a small hook like steel piece with a tail like extension mounted so as to rest beside a small projection on the spring clutch shaft. This prevents the declutching of commutator shaft from the spring clutch shaft whenever the operating handle is turned from Line Closed to TCF or TGT positions as it butts against this projection. In the turned positions of the handle, the projection moves away from the safety catch, and this permits the declutching of the commutator shaft when token is inserted and the plunger pressed. This action causes only commutator shaft to rotate back due to the push of the forked lever on the token, thus normalising the commutator to enable normalisation of the instruments for closing the Block Section. Refer Fig.No. 1.17A If this safety catch were not provided, and should the commutator shaft get stuck upon the spindle due to a mechanical fault when the operating handle is being turned from line closed to TCF position for granting line clear, the spring clutch shaft would declutch and turn over with the operating handle leaving the commutator normal. Since the commutator has not changed, the instrument at the other end cannot be turned to TGT position causing block failure. Should this sticking up of the commutator shaft takes place in the instrument receiving "Line Clear" then the handle would have been turned to TGT, obtaining a token. After sending the train, the train receiving instrument can be normalised since the commutator is Normal at the train despatching end and the sending instrument can also be normalised subsequently. Both instruments of the Block Section are Normal with a train in the Block Section. By repeating this process, a number of trains can be sent in the Block Section one behind the other thus violating the principles of Absolute Block System and endangering safety. 14

Should the commutator sticking up taking place intermittently the sending station after normalising the instrument will be in a position to grant line clear to the other end station, thus allowing a second train in the opposite direction into the Block Section. With the provision of this small gadget, the above unsafe conditions are prevented. Hence, the name Safety Catch.

This is provided in the instrument to RDSO Drg.No.SA/20701/M. The purpose of this is to prevent the commutator bouncing back when the handle is in TCF/TGT position with a token inserted and plunger pressed. On its frequent operations there is a chance for its loosening and dropping into the races which may create failures. Hence, adequate care is to be taken for its proper functioning.

The token selector is concentrically mounted on the operating handle extension inside the instrument and then determines from which race the token shall be selected for issue out of the instrument. It has two recesses each of a size to receive one ball token. The token selector is connected through a rod, to the rod connecting the toothed sector to the spring clutch shaft in such a manner that when the operating handle is turned to either of the horizontal positions, it revolves only in anti-clockwise direction (viewed from the rear) and when the handle is brought back to the vertical position, it revolves back in clockwise direction to its original position. This movement of the token selector, every time the operating handle is turned from one position to another, shifts all the tokens in the four races slightly up or down, thus preventing any tendency to jam or hangup in the races. With the handle in the vertical position, the two recesses in the selector are open to races 1 and 3 (viewed from the front of the instrument and counting from left to right), and with the handle in either of the horizontal positions TGT or TCF, they are open to races 2 and 4. The order in which the tokens are selected from various races is as follows:First all tokens from race 3, then all from race 4, then one token from race 1, and then all tokens from race 2 and finally all from race 1 (Fig.1.22).

Fig. 1.22 DETAILS OF TOKEN SELECTOR WITH TOKEN RACES

This is a mechanical indicator which gives an indication to the operating staff whether any token is present in the bottom handle or not. This works on the principle of gravity drop. An 'S' 15

shaped swinging lever is pivotted on the token selector plate (forming a housing for the token delivery drum). The top end of this carries a flag indicator painted red and green and mounted in such a manner as to be seen through a glass opening in the front of the instrument. Its bottom is rounded off and presses against a token in the token drum. In this position, the indicator displays a green indication. Should there be no token in the operating drum, the lever revolves under its own weight and the rounded end enters the empty spaces in the token delivery drum locking the same and consequently, prevents bottom handle being turned to TGT position when there is no token in the instrument, and changing the indication (seen through the indicator), to "Red". This, however, does not prevent bottom handle from being turned to TCF position. The details are shown in Fig. 1.23.

Fig. 1.23 TOKEN INDICATOR (S20745) (As viewed from front)

This simple gadget serves to prevent the Block Handle to be turned from Line Closed position to ‘TGT’ position when the tokens are exhausted in the instrument. The facility of cancellation of line clear is an inherent feature of any Block Instrument in order to cater to the Traffic need of change in the programme of movements of trains in emergencies or other exigencies. In case the Block Handle assumes TGT position with out a token delivered from out of the instrument when tokens are exhausted, it will not be possible to cancel Line Clear because a token is required to effect the change of commutator. In the absence of this simple mechanical device, once the Block Handle assumes TGT position without delivering a token both the Block handles of an interconnected pair of instruments get locked up-one in TCF position and the other in TGT position and cancellation of Line Clear is not possible. This ends up in an impasse or a dead lock necessitating the attendance of authorised official of S&T Department for restoring normal working by balancing of Tokens or by Phasing. At times this involves considerable duration of failure and in the mean time trains have to be worked on paper Line Clear Ticket in both directions even though all the tokens are accumulated in the other instrument. Since this gadget is provided normal Block working can be restored with out S&T official once a train is received from the other station. Thus this modest gadget renders a safety function solemnly. i) Mechanical: A separate side lock is attached on the TGT side of the instrument. A small extension piece working into the lock is screwed on to the rack on the TGT side. In the normal and TCF positions of the operating handle the plunger of this lock will be fouled by the 16

extension piece of the rack and the key of the same cannot be taken out. In the TGT position of the operating handle only the rack comes out of the lock enabling it to be locked by taking out the key. This key is utilised to take off the Last Stop Signal either by inserting it in the mechanical lock on the LS.S. lever or utilising it to release the SM's control instrument. Once this key is taken out of the lock, the lock plunger will foul the rack and the operating handle cannot be turned from the TGT position unless and until the L.S.S. Control Key is brought back, put into the lock and turned. The details are given in Fig. 1.24(i).

Fig : 1.24 (ii) LAST STOP SIGNAL CONTROL (Electrical) A stud screwed on to the lock replacer disc which is called TGT stud bridges two contact springs when the block handle is turned to TGT position. The last stop signal reverser feed is taken through this contact, ensuring that the last stop signal can be taken off only when the block handle is turned to TGT position.

17

It has since been ordered by the Railway Board that on single line section where Tokenless Block Instruments are not provided, the following controls must be provided on the Last Stop Signal. i) one train/one line clear. ii) Provision for automatic replacement of Last Stop Signal, with the passage of train. The Board have further ordered that the above should be catered for in all future works and should be carried out in the case of existing installations, on a programmed basis. A Typical LSS control circuit confirming the above provisions is illustrated in Fig.no.1.24 (iii)

Fig : 1.24 (iii) TYPICAL LAST STOP SIGNAL CONTROL CIRCUIT

A telephone is superimposed on the block line through an induction coil and a 1 MF isolation condenser. The condenser isolates the telephone circuit from the Block instrument circuit. The telephone is HMT type. The primary circuit of the induction coil works with 2 primary cells. A simplified telephone circuit is shown in Fig.1.25.

Fig : 1.25 SIMPLIFIED TELEPHONE CIRCUIT In a pair of Neale's instruments used for a Block Section the wiring for the instruments is not identical. The two methods of wiring are:-

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NORMAL POLARITY INSTRUMENT

REVERSE POLARITY INSTRUMENT Fig : 1.26

instrument is one which normally, i.e., in the Line Closed Position of the operating handle, would connect positive of the battery to the line when the plunger is pressed and also would require a positive potential on line to enable its operating handle to be turned to "Train Going To" Position. instrument is just the opposite i.e., it would connect negative to line in the "Line Closed" position of the operating handle when the plunger is pressed and would require negative potential on the line for taking the operating handle to "Train Going To" position. In a pair of instruments used for on Block Section, one should be of Normal polarity wiring and other of Reverse Polarity wiring. The reason for providing a pair of such instruments for a Block Section is to prevent the possibility of simultaneously obtaining two tokens, one at each end of the section, in the event of the Block Line coming in contact with another conductor of favourable polarity. A normal polarity instrument can be converted into Reverse Polarity (or vice-versa) by reversing the connections of:(i) Needle Indicator (ii) Polarised Relay and (iii) Line Battery. 2 sets of batteries are used for this instrument. (i)

Line Battery (ii) Telephone Battery.

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Fig : 1.26 NOTE : -20

1.

I) BOTTOM HANDLE NORMAL - Commutator Normal ii) Bottom Handle in TCF or TGT - Commutator Reverse iii) Bottom Handle in TCF or TGT - Commutator Normal Token inserted & Plunger pressed.

2.

iv) Spring No. 1,2 & 3, 4 Are made when commutator is normal and plunger pressed. v) Spring No. 1.4 & 2.3 are made when commutator is reverse and plunger pressed. vi) Spring 5 is normally connected to rest contact to connect the PR to line and get disconnected when plunger is pressed to isolate PR when an out-going current is put on line.

3.

I) TCF lock to be energised to operate bottom handle from

4. 5.

ii) TGT lock to be energised to operate bottom handle from N to TGT iii) RC-Resting contact Interstroke interrupter’s contacts are normally made but gets interrupted momentarily when bottom handle is being operated. Normal Polarity: i) ii) iii) iv)

6.

N to TCF TCF to N TGT to N

When commutator normal and plunger pressed connects positive on line When commutator reverse and plunger pressed connects negative on line. Requires positive on line for TGT lock. Requires Negative on line for TCF lock.

Reverse polarity: i) ii) iii) iv)

When Commutator normal and plunger pressed connects negative on line. When commutator reverse and plunger pressed connects positive on line Requires negative on line for TGT lock Requires positive on line for TCF lock.

The operation of the Block Instrument of a section for a Train Movement are as under:The Schematic Diagram of a pair of interconnected Token Block Instruments is illustrated in Fig.1.26 A & B are two adjoining stations (Fig.1.26) provided with normal and reverse polarity instruments respectively connected by overhead line wire and earth return (Metallic return, where necessary, may be provided) Station Master at 'A' has to despatch a train to B. A asks B for "Line Clear" by sending the authorised bell code signals and prolongs the last beat. The circuit is shown in Fig. 1.27(i).

21

Needle Indicators at 'A' and 'B' deflect to the right. The tongue of the polarised relay at 'B' deflects to 'R' completing a local series circuit of block Bell and TCF Lock Coil. When the Handle is being turned at 'B' there will be a jerk in the indicator needle, both at A and B due to the interstroke interrupter (jerking contact) momentarily breaking and again making. The Operating Handle having been turned at Station 'B' to TCF position the commutator is reversed at that station. Plunger at 'B' if pressed will now send a positive current on line. 'B' now sends authorised bell code signals to 'A' and prolongs the last beat. The circuit is shown in Fig. 1.27(ii).

Fig : 1.27 (II) The tongue of the polarised relay at "A" is attracted towards "N" completing local circuit for the block bell and TGT lock coil in series. There is one bell beat at 'A' and the TGT coil being energised, its armature is operated. When operating handle at "A" is pulled for operation, the TGT Lock Pawl is lifted and the handle is free to be turned to TGT position. While the operating handle is being turned to TGT position, if the train receiving station releases the plunger, the operating handle at the despatching station gets locked in the check lock position and cannot be fully turned to TGT position unless continuous co-operation is given by the train receiving S.M. When the handle is taken to the TGT position the commutator at "A" is reversed and a token is delivered. In this position of the operating handle, either the last stop signal control key can be extracted (Fig. 1-24 (i)/(iii) or the Last Stop Signal electrical control contact is made. In the case of mechanical control, the key extracted from the Block Instrument is used either in the Station Master's control apparatus or in the Signal Lever controlling the Last Stop Signal. Once a train clears the Last Stop Signal, the Signal is put back to " ON " position. Train entering section code is sent to the station in advance. The Last Stop signal control key (where provided) is restored into the Block Instrument at "A". Driver on arrival at "B" hands over the token to Station Master. Station Master at "B" calls attention of Station Master at "A" and on being acknowledged inserts the token into his instrument and gives bell signal for "train out of section",. This changes his commutator to Normal. "B" prolongs the last beat and Station Master at "A" observing the indicator needle 22

deflecting to the right turns the operating handle from TGT to "Line Closed" position. This changes his commutator also to Normal. The circuit is shown in Fig.1.27(iii).

Fig : 1.27 (III) “A” now acknowledges the “Train out of section” Signal prolonging the last beat. Commutator at “A” having been changed to Normal, the prolonged beat energises the TCF coil at ‘B’ enabling him to turn his operating handle from TCF to “Line Closed” position. The commutator at “B” having already come to Normal position when the token was plunged in, turning of the operating handle at “B” has no effect on the commutator. Both instruments are now in “Line Closed Position”. The study of the circuit will reveal that there is no possibility of a second token being extracted from either of the instruments when the Block Section is already occupied by a train even with the Mutual Co-operation of Station Masters at both ends. Let us assume that the Station "A" has despatched a train towards Station "B". As the commutator of the instruments at both the stations are in reverse, the polarity of the current that can be transmitted both from A as well as from B will be suitable to pick up only TGT lock at the other end. As the operation of the handle either from TGT or TCF position requires TCF lock coil to be energised picking up of TGT lock as above is of no use. This ensures the locking of the instrument at Station "A" in TGT and at "B" in TCF position and thus preventing extraction of a second token. Wiring Diagram (S.20911) for a pair of Ball Token Block Instruments is illustrated in Fig. 1.27. The Wiring relates to the use of Ω 3 position in which the tongue of the PR deflects to Right Hand Side and TCF coil is energised when the positive Terminal of the Relay coil R1 is fed positive supply. After standardisation 77 Ω DC polarised Relay – 3 position (S31/80) is used in which the tongue of the PR deflects to Left Hand Side marked as N-(Normal position) when the positive terminal of the polarised Relay coil R1 is fed positive supply. 77 Ω Relays to specification S31-80 shall be used for Block circuits the wiring diagram S20911 needs corresponding changes to suit the standard arrangement using 77Ω Relay S31-80. The schematic wiring of the block instruments using 260 Ω polarised relays is shown in Fig 1.27 A . Differences in wirings can be observed with a reference to Fig 1.26. ( Schematic Diagram of Token Instruments Using Standardised 77 Ω Polarise relay – S 31- 80.

23

Fig.1.27 A 24

After obtaining line clear and extracting a token, if Station Master at "A" does not despatch a train for any reason, he can cancel the "Line Clear". "A" informs "B" about his intention of not despatching the train and inserts the token into his instrument. "A" sends bell signals to "B" for cancelling "Line Clear" prolonging the last beat. The insertion of token and plunging changes his commutator. The polarised relay at "B" is energised to release the TCF lock which enables him to turn his operating Handle from TCF Position to "Line Closed" position. Station "B" acknowledges the cancelling signal prolonging the last beat. This enables "A" to turn the operating handle from TGT to "Line Closed" Position.

Note: - Station Master on duty is responsible to ensure that no unauthorised person loiters near or operates the Block Instruments Despatching a train in Neale' s Ball Token or Tablet, Token Instrument sections

(1) Insert Station Master's key and turn. (2) Give 'Attention' signal. (3) Insert Station Master's key and turn. (4) Acknowledge. Attend Telephone and give out Station Name. (5) On receipt of acknowledgement attend Telephone. Give out Station Name. (6) Ensure correct station has responded. Give Number and Description of train. (7) Ensure correctness of station. Repeat Number and Description of train. If line is clear, give Private Number. (8) Repeat the Private Number. (9) Give 'Attention' signal. (10) Acknowledge ‘Attention ‘ Signal. (11) Give 'Is Line Clear' signal. Prolong the last beat. (12) Observe needle points to right and turn the Operating Handle to 'Train Coming From' position. Acknowledge ‘is Line Clear’. Prolong the last beat till the needle of Galvanometer jerks. (13) Observe needle points to left and turn the Operating Handle to 'Train Going To'. A Token comes out. 25

(14) Give 'Attention' signal. (15)Acknowledge. Telephone.

Attend

(16) Give Token No. (with class). (17) Receive Token No. (with class) Repeat it. (18) (a) Take ' OFF' Last Stop signal. (b) Hand over Token to the Driver. (c) On train entering section put back Last Stop signal to ' ON'. (19) Send 'Attention' signal. (20) Acknowledge Attention signal. (21) Give 'Train Entering Section signal. (22) Acknowledge 'Train Entering Section ' signal. (23)

(a) Take 'OFF' Reception signals. (b) Ensure train has arrived complete. (c) Put back Reception Signals to ‘ON'. (d) Obtain the Token from the Driver. Ensure its correctness. (24) Give 'Attention' signal. (25) Acknowledge signal.

Attention (26) (i) For Neale's Ball Token Instrument.-Insert Token into Token Receiver and turn Token Receiver Handle. (ii) For Neale's Tablet Instrument.-Draw out the Token slide keep the Tablet in the space provided push back the Token slide. (27) Give 'Train Out of Section' signal. Prolong the last beat.

(28) Turn the Operating Handle to 'Line Closed '. Acknowledge ‘Train Out of Section ' signal. Prolong the last beat.

(29) Turn the Operating Handle to ' Line Closed '. 26

Note :- Before turning the Operating Handle, it should be ensured that the Galvanometer is deflecting correctly as under (i) Both Instruments of the Block section in 'Line Closed' position - Incoming and outgoing beats give clockwise deflection. (ii) Both Instruments not in 'Line Closed' position and a Token out - Incoming and outgoing beats give anti-clockwise deflection. (iii) One or both Instruments not in 'Line Closed' position and no Token out - Outgoing and incoming beats give deflections in opposite directions. The Neale's token instrument shall be considered as having failed and working of the Block Instrument shall be suspended in the following circumstances:1) 2) 3) 4) 5)

When bell signals are received indistinctly or fail altogether. If the needle of the galvanoscope fails to move when bell signals are given or received or shows a wrong indication viz., to the right instead of left and vice versa. When a token is broken or damaged in any way during or after extraction. If a token cannot be taken out from the instrument after proper signals have been exchanged and no token is out from either instruments of a section. When a token can be taken out from the instrument without proper signals being exchanged with the station at the other end of the section.

Note: This test shall be made when the operators take charge of the block instrument. 6)

If a token cannot be put back into the instrument or jams when being put back into the instrument. 7) If a train arrives at a station without a token referring to the Block Section over which the train has passed. 8) When the token belonging to a block section has been overcarried to another station, or is lost and cannot be found. 9) When there is no token in the instrument at the station from which a train is ready to start. 10) When there is a reason to believe that there is contact between the Block wire and any other circuit. Note: If a contact exists between the block wire and any other circuit, there will be either a permanent or intermittent deflection of the needle in the dial and possibly irregular beats on the bell. A contact between two block wires of adjacent sections would cause signals if given on one instrument to be repeated on the adjacent instrument. 11) 12) 13) 14) 15)

If the operating handle cannot be turned to any one of the three positions with a prolonged beat from the distant station. If the operating handle can be turned to any one of the three positions without a prolonged beat from the station at the other end. If the dial glass of the galvanoscope is broken. If the instrument or its battery counter is found unlocked. When the key of the token receiver drum is lost or the lock is out of order.

16) When the key of the clamp locked on the token handed over to the preceding train, is returned to the station in rear by the officer in charge of the motor trolley following that train. 17) When a private number cannot be obtained from the Station Master at the other end of the section through the Block Telephone. 18) If it is known that the instrument is defective in any way not specified above. 27

A sealing screw is provided in the back of the instrument which can be used for sealing. In addition to this sealing facility, locking arrangement is also provided to lock the instrument by Maintainer. Double Locking of the instrument and also Locking and Sealing of the Block Counter as stipulated in SEM shall also be complied in the construction of the instruments and in maintenance. 1.32

for Token Instruments are furnished in the booklet STS/E/BTI/IMI published by RDSO during Jan., 1978.

General Requirements and Special requirements of Block Instruments are incorporated in SEM Chapter VII –Section N. Instructions for installation and maintenance of Block Instruments as laid down in SEM (Chapter XVIII ) and the Schedules with their periodicity as described in Annexure - 28 ( Para 18.57.) shall be followed .Registers of recording of Checks , Tests, Measurements etc. shall be maintained. Some of the points on Do's and Don'ts. a) Do not bend the contact spring specially the finger contacts, unless absolutely necessary to obtain contact pressure. b) Do not allow the block instrument in circuit if the safety catch on spring clutch shaft is either broken or not functioning properly. c) Do not file the rack notch or lock pawls. If they are not properly engaging remove them and adjust. d) Do not open the polarised relay. If the seal is broken for any reason, it must be removed from the circuit. e) Do not make the Station Master's lock up contact through under any circumstances. RDSO/Lucknow, through their Lr.No.STS/E/BT1 of 22/26-3-91, have recommended the following precautions to be taken for the section equipped with Neale's Token Block Instruments:i) It is desirable to have metallic return to take care of Multiple failures, as recommended in the Block Manual. ii) The block wires should be placed on top of the alignment so as to preclude the possibility of foreign feed injection into the block line. iii) Lightning discharger of striking voltage greater than the normal working voltage may be provided at both ends of the block line.

It is similar to the Neale’s Ball Token Instrument in its electrical and many mechanical features. The only point of difference between the two is that the token used in this case is a flat circular tablet, as against a round hollow steel ball. Hence, certain parts of the instrument, 28

that receive, store and deliver the tablet token have been modified to suit this configuration. A front view of the instrument is shown in Fig.2.1. In general this instrument is much smaller and lighter. It actually weighs nearly two thirds the weight of the ball token instruments.

Fig : 2.1 TABLET TOKEN INSTRUMENT The parts of the instrument that differ from the ball token instrument are listed below:1) Tablet Tokens 2) Top slide with handle and tablet receptacle 3) Tablet guide rods (slide rails) 4) Bottom slide (Tablet outlet slide) 5) C a m 6) Cam Strap (Tablet outlet slide lever) 7) Tablet Releaser (Lever) 29

8) Tablet Receiver 9) Tablet Window (Token Indicator) 10) No token indicating lock (pawl) 11) Contact making spring assembly arrangement. 2.3

The tokens used are steel disc tablets, got two notches, the tablets are 6 mm. thick and have a dia of 73 mm.

FIG : 2.3 NEALE’s TABLET TOKENS CONFIGURATIONS Each tablet got two notches cut for guiding them for consigning and properly storing the tablets in the instrument. Besides, these two notches two additional notches are also cut on the periphery of the tablet, the position of the notches being suitably varied to get 5 different classes of tokens for the five different classes of Neale's Tablet viz., Class A,B,C ,D and E. The arrangement of notches for different classes of Tablets is shown in Fig. No.2.3. In order to facilitate easy identification for the class of tokens, an additional hole of following configuration is cut in the centre of each tablet. Class A - Circle Class B - Square 30

Class C - Rectangle Class D - Triangle Class E - Rhombus It is a rectangular steel slide provided at the top of the instrument. Near its one end, a hole is cut to take one tablet corresponding to the class of the instrument. A knob or handle is provided at the other end to enable the slide to be pulled out of its housing to expose the recess to take a token and subsequently rushed in, to consign it into the instrument. The tablet receptacle has two diametrically opposite semicircular projections to correspond with notches in the tablets. There are two other projections located suitably on the circumference of the receptacle to correspond to the notches in the tablets determining the class of the instrument. This is again to ensure that tokens belonging to instruments of one block section cannot be wrongly consigned into the instrument belonging to an adjacent block section. The top slide housing has a gravity operated lock pawl which prevents the slide being pushed in either with its receptacle empty or carrying objects not conforming to the standard dimensions of the tokens used. A SM's lock is also provided to prevent unauthorised manipulation of the slide in the absence of the SM as the Key is in his custody. (Slide Rails): Two vertical cylindrical guide rods are provided, diametrically opposite each other at the right of the instrument. (Seen from the back). They are fixed so that they align immediately below the semi-circular projections on the tablet receptacle when the top slide is pushed in with the token. This allows the tablets to slide down between the guide rods and get piled one above the other in the instrument. (Tablet outlet slide): It is triangular in shape, with a suitable hole to hold one tablet at one corner and two studs at the other, one stud serves to pivot the slide and the other couples it to the operating handle, through a cam strap and cam arrangement in such a manner as to rotate it over an area about its pivot with different positions of the operating handle. In line closed position of the operating handle, it opens its recess underneath the two guide rods so as to receive the bottom most tablet and subsequently deliver it out of the instrument. In this position the tablet in its recess does not drop down because the bottom slide is resting on a guide plate at the bottom. When the operating handle is pulled out and turned from Line Closed to TGT position the bottom slide moves over an arc in an anti-clockwise direction (as seen from back side) bringing the recess of the bottom slide (carrying the token) over a sloping channel formed at one end of the bottom guide plate, leading to the exit window. So long as the handle is in its pulled position a tablet releaser comes underneath the bottom slide recess and prevents the tablet dropping down, delaying the issue of the tablet until the handle sits into its slots in the TGT position and the tablet releaser is withdrawn from underneath the bottom slide. The third corner of the bottom slide now moving under the guide rods prevents the next tablet falling on to the bottom guide plate. The Cam is mounted on the operating handle extension to control the movement of the bottom slide for issue of a tablet when the operating handle is turned from Line Closed to TGT position only. It also brings the bottom slide back to its initial position to accept another tablet in its recess ready for issue for the following operation, when the handle is turned back from TGT to Line Closed position. For this the cam is mounted to the bottom slide through cam strap. (Tablet Outlet Slide Lever): It is rectangular in shape, mounted so as to enclose the cam on the operating handle. One end of the strap is coupled to the operating pin 31

on the bottom slide and the other end has an elongated slot which is guided on a stud screwed to the base. When the operating handle is turned from Line Closed to TGT position and back, the cam displaces the strap sideways from right to left and back again as viewed from the rear side of the instrument. The bottom slide follows the movement of the strap. The cam does not move the cam strap when the operating handle is turned from Line Closed to TCF position and back. Hence, there will be no movement of the bottom slide. The details of the cam, cam strap and the bottom slide are shown in Fig. 2.8.

Fig : 2.8

CAM ,CAM STRAP AND BOTTOM SLIDE

(Lever): This is an arc shaped lever situated near the exit window. This is operated through a link mechanism by the operating handle as shown in Fig.2.9. The purpose of this lever is to ensure that the tablet is issued out of the instrument only when the operating handle has been locked by the TCF lock pawl in TGT position. This ensures locking of the operating handle as it fits in the slot in TGT Position. A collar is mounted on the operating handle. In the pulled position of the operating handle this moves the tablet releaser underneath the bottom slide recess carrying the tablet through a link mechanism. This prevents the issue of a tablet, even though the tablet on the bottom slide has been brought over the exit until the bottom handle is housed in its TGT position.

32

Fig : 2.9 .1 TABLET OUTLET SLIDE

33

( BOTTOM SLIDE)

Fig : 2.9.2

TABLET RELEASER

This is an extended portion of the commutator shaft which in the reverse position of the commutator (when the handle is in TGT or TCF position) allows a token consigned into the instrument through the top slide to rest on it preventing it from going right down into the bottom, along the guide rods. This serves the same purpose as the jaw on the commutator shaft in the ball token instrument. When the plunger is pressed, with the handle in any of the two horizontal positions (a tablet having been inserted already) the fork lever attached to the finger spring assembly shaft presses down the tablet along the guide rails at the same time turning the commutator to normal position. (Token Indicator): It is a small glazed opening on the bottom left of the instrument. Through this the presence of tablet lying piled one above the other in the instrument can be seen. The second token from bottom i.e., the one lying immediately above the one in the tablet receptacle on the bottom slide is the lowest tablet that can be seen. (Pawl): A small gravity operated lock pawl is mounted on the bottom guide plate so that this is normally projecting into the circular hole cut in the bottom slide. This is a small steel piece eccentrically mounted so that one end of it is projecting up, the other end being pulled down by its own weight. Because of this when the operating handle is turned from Line Closed to TGT position without any token in the instrument forward motion of the bottom slide is arrested and hence, the handle also. When a tablet is in the instrument, lying in the recess in the bottom slide, the locking pawl is pressed, flush with the guide plate by the weight of the tablet. The contact making spring assembly is almost similar to that of the Neale's Ball Token Instrument except the change in numbering.

34

Fig : 2.13 CONTACT ARRANGEMENT The instrument offers the following advantages over the Ball Token Instrument:i) The height of the instrument is much reduced, thereby reducing the weight considerably. This is made possible because tablets occupy less space for storage in the instrument than the ball tokens. ii) Even with its reduced dimension, it can hold 40 tablet tokens as against 36 in the ball token instrument, but, normally each instrument is supplied with 16 tablets only unless otherwise stated. iii) The absence of token races preclude the possibility of tokens jamming in the races and preventing the operating handle being turned, which sometimes causes failures in the ball token instrument. iv) Should tablet escape from its pouch when being picked up or dropped by a run through train, the possibility of its rolling away and getting lost is remote, because it is a flat object. v) Sequence of tokens is maintained. Hence, the number of tablets in the instrument can be verified from TSR and any cancellations done, but not entered in the Register could be detected. 35

Note: TSR - Train Service Register. The reduced dimensions of the tablet token instruments have necessitated re-orientation of the various mechanical parts. The polarised relay and the bell assembly are placed on the left (the former above the latter) as looked at from the back of the instrument. The commutator with the finger contact spring assembly is mounted on the right and the jerking contact springs behind the spring clutch shaft in the middle. Hence, the jerking contact springs and segments are not available for easy inspection as in the case of ball token instrument (Ref. Fig.No.2.15). All the other mechanical parts, electrical circuitry and also the methods adopted for control of Last Stop Signal are identical with the ball token instrument and are not repeated here.

36

37

There are 3 types of Double Line Block Instruments:1) SGE Type (Byculla Make) 2) IRS Type (HWH Make) 3) SGE Modified Type (PTJ Make) The main differences among them are:i) Contact arrangement ii) Housing of components like polarised relay, Bell Assembly, Bell Relay, Telephone etc. iii) Design of TOL Lock (Mechanical stick or Electrical Stick). Though there are differences in the design aspect, all the three types are approved for use in RE and Non-RE sections. A detailed study of SGE type Block Instruments is dealt in the foregoing paras. This is a three wire three position double line block instrument. The indications for the up and down directions are controlled by one wire each and the bell and telephone are worked by the third wire, earth being employed for return circuit. In cases where interference from extraneous currents is likely to occur, a metallic return may be provided for the block lines leaving the bell communication to be worked by earth return. The instrument consists of two needle indicators placed one above the other. A commutator, with a bell-plunger threaded through its middle is provided below the bottom indicator. The single stroke bell for exchanging code of bell signals, is provided as a separate unit. A front view of the instrument is shown in Fig. 3.2

Fig : 3.2 FRONT VIEW OF SGE DOUBLE LINE BLOCK INSTRUMENT In this double line block instrument, the indicator which is operated by the commutator is placed above to the latter, and the commutator is operated only by the advanced station 38

operator when he receives a train. Therefore, the bottom indicator of the instrument which is nearest to the commutator refers trains coming from the adjacent station to which the instrument is connected and the top indicator refers to trains going to the adjacent station of the same Block section. This is a simple block instrument wherein the advanced station operator has to operate the commutator of his instrument during the three stages of receiving a train i.e., 1) while granting 'Line Clear' (ii) when the train has entered the block section at the rear station and (iii) when the instruments are again normalised after the complete arrival of that train. By providing an electric lock on the commutator when it is in the "Train on Line" position and by adding other controls in the form of external circuits advantages of Lock & Block working are obtained electrically. The indications of the Bottom indicator correspond to the positions of the commutator. The parts of the instrument are described below:(Upper Needle): It is a polarised indicator. The needle of the indicator normally hangs down vertically due to gravity, from its top, and points to "Line Closed" indicating on the dial. This indicator is connected by a line wire to the bottom indicator (Lower needle) of the instrument at the other end of the Block Section so that whenever a battery is applied to this line by the commutator at the distant station (advanced station) being turned this indicator shows 'Line Clear' or 'Train on Line' according to the polarity on the line. When the commutator is operated and the battery negative on line energises this indicator, it deflects to right and the arrow points to 'Line Clear' indication on the dial. When battery positive on Line actuates the indicator the needle deflects to left and points to 'Train On Line' indication. As already said this indicator refers to train going away from the station into the concerned Block Section. The coil of this indicator is wound to a resistance of 140 Ohms and it works on an operating current of 17 to 25 mA. (Lower Needle): This is identical to the top indicator. This being the indicator nearest to the commutator, is operated whenever the commutator is turned. Whenever the train receiving station (advanced station) operates the commutator this indicator shows 'Line Clear' or 'Train On Line' depending on whether negative or positive polarity respectively is applied to Line through this indicator. This indicator is connected electrically to the top indicator of the instrument at the rear station. So, whenever the commutator is operated this indicator at the advanced station and the top indicator at the rear station show the same indications (which are of course dependent on the direction of the current on Line). The coil of this indicator is also wound to a resistance of 140 Ohms and it works on an operating current of 17 to 25 mA. This indicator refers to trains coming towards the station. This indicator is also known as TCF Indicator. A single stroke block bell is worked by a relay. The resistance of this relay is 500 Ohms and it requires a minimum operating current of 7.5 mA. The relay and the bell form a separate unit. The bell relay is worked by a separate line wire. This is a single stroke bell actuated by the bell relay. The resistance of the bell coil is 60 Ohms. It requires a minimum operating current of 85 ma whenever the plunger at the distant station is pressed, this bell registers one beat. This is threaded through the centre of the Commutator Handle. The metallic end of this plunger rod normally bridges, two springs, one connected to the bell relay coil and the other to the bell line. When the plunger is pushed in, its end breaks the normal connection and connects the line spring to another spring which is connected to the bell battery positive. Thus every time the plunger is pressed, the battery positive is applied on the bell line completing the circuit through the bell relay at the distant station and earth. Thus the bell at the distant station is actuated when the plunger is pressed. 39

Commutator Handle turns to 200 left and to 200 right from the vertical position, marked by an arrow. The movement of the Handle causes the Commutator Disc and the Commutator to turn. The Bell plunger is threaded through the centre of the Commutator Handle. A disc called Commutated Disc mounted below the Bottom Indicator in the middle of the instrument is attached to the Commutator Handle. A pin called Commutator Pin on the Bell plunger when at rest passes through this Commutator Disc and the back of the front cover plate and therefore, prevents the Commutator from being turned when the plunger is pressed. The pin moves out of the back of the plate thus releasing the Commutator for its operation. The Commutator Handle can not be turned from one position to the other unless the Bell plunger is pressed. This means every time the Commutator has to be turned, the Bell plunger must be pressed. Incidentally Single stroke Bell is actuated at the other end drawing the attention of the SM, whenever the Commutator is turned. To bring 'Line Clear' indication in the bottom indicator of that instrument and the top indicator of the interconnected instrument, the Commutator Handle is turned clockwise through about 200 from Normal (Line Closed). It is turned anti-clockwise through the same angle from the mid-position to get the 'Train On Line' indication in the respective indicators. The commutator disc moves over a spring loaded ball at its bottom which gives easy movement to the commutator. A fan shaped ebonite plate is attached to the commutator disc. This plate carries four commutator segments. There are six commutator springs, mounted in front of the commutator segment bearing plate. In the 'Line Closed' position of the commutator the contact segments are free of the commutator springs. The first and sixth springs, as seen from the back are connected to earth, the third and fourth springs to the line, the second spring to battery positive and the fifth spring to battery negative. When the commutator is turned to the 'Line Clear' position, the top contact segment on the left (as viewed from the back) puts through the battery positive to earth and the bottom segment or the right connects battery negative to line. This negative polarity is connected to line through the bottom indicator of the instrument. This brings 'Line Clear' indication via the bottom indicator at the advanced station and the top indicator of the rear station instrument. When the commutator is turned to the 'Train On Line' position, the top contact segment on the right connects battery negative and Earth springs and the bottom contact segment on the left connects battery positive and line springs. Thus the polarity to line is reversed and the indications of the indicators of the two instruments of the section also change to 'Train On Line' . In the 'Train On Line' position of the commutator, the top contact segment on the left puts through two other springs. This contact is included in the Block Clearance Circuits.

3.10A COMMUTATOR SEGMENT ARRANGEMENT (S.G.E) This design is different from the C.Rly Byculla make (SGE)

40

In the S. Rly PTJ make instrument the commutator shaft carries six rotary contacts. Six segments are mounted on a shaft and six contact springs are fixed vertically on either side of the segments on to the base for this purpose.

Two pairs of springs – used for Line Clear Indication circuit. Two pairs of springs – used for Train on Line indication circuit. One pair of springs - used for initiation of block clearance circuit.(i.e. ZR circuit) One pair of springs - used for completion of Block clearance circuit (i.e. ZR and its stick circuit)

3.10B COMMUTATOR CONTACTS (REAR VIEW) In S.Rly PTJ make instrument.

In the E. Rly HWH make instrument, the function of commutator is achieved with the design of 9 way drum with slotted segments. Contacts are closed when split spring strips are made to move over these segments when the commutator is operated. A lock is provided on the Commutator Handle in order to fulfil the essentials of (Lock and Block Working) interlocking between signals and Block instrument on Double Line. Means shall be arranged to prevent Line Clear being given by the Block station in advance, until the preceding train has cleared the Block Section, the overlap and also the Block Signals have been replaced ON. The Commutator Handle is free to be turned (i) from Line Closed to Line Clear (ii) from Line Clear to Line Closed. and (iii) from Line Closed to Train on Line.

The lock is effective only in TOL position, that too ‘conditionally’ such that

41

(i)

the commutator Handle is locked when it is turned from Line Clear to TOL in connection with a running train for which Line Clear has been granted and the lock is released electrically by the arrival of the train for which Line Clear is granted. and

(ii)

the Commutator Handle is not locked in TOL position when it is turned directly from Line Closed to Train on Line in connection with a non-running train (i.e. in case of Block Forward for shunting in advance of LSS at the rear station). As there is no lock in TOL position when the commutator is turned directly from Line Closed to TOL for Block Forward operation, the commutator is brought back to Line Closed position after the shunting train returns clearing the FVT. This helps to restore SR at the rear station which is de-energised during shunting over FVT. Otherwise SR drops due to shunting over FVT cutting off the stick feed to SR and resulting in Failure of LSS when Line Clear is granted for a train after the Block Forward shunting operation.

The Lock on commutator is also called ‘Door-Lock’. This conditional Locking on Commutator is achieved by a special mechanical arrangement called Door Lock mechanism in SGE type (Bycula C.Rly make) and HWH E. Rly make). The armature of the electromagnet is normally (i.e. when not energised) prevented from falling on the commutator disc due to a mechanical catch (Holding Pawl). When the commutator is turned to the "Line Clear" position from Line Closed, the pin of the bell plunger pushes the holding pawl aside and the armature drops on the periphery of the commutator disc. Normally. a small releasing lever at the top rests on a holding pin at the back of the holding pawl at its top end. When the holding pawl moves aside this lever drops as it is pivotted at one end and has the releasing bracket attached to its middle. This release lever on falling down comes to rest on a resting pin and presses against the holding pin and prevents the holding pawl from returning to its original position. After having been turned to 'Line Clear' if the commutator is turned to 'Train On Line' position the armature, resting on the commutator disc, drops into the locking notch of commutator. This locks the commutator and it can be released only when the door lock coil is energised and its armature attracted out of the notch, which will happen only when the train for which Line Clear was granted has arrived inside the block clearance point at the advanced station and the reception signals have also been put back to danger behind the train, satisfying the conditions of Lock and Block working When the door lock coil is energised the attracted armature lifts up the releasing bracket which in turn pushes up the release lever. The release lever having been lifted and there being no obstruction against the holding pin, the holding pawl swings back to its normal position below the armature ready to catch the latter when it drops down after the door lock coil having been de-energised. If the armature should get struck up due to residual magnetism or any mechanical defect there would not be any locking of the commutator in the TOL position, the instrument would become a "free" block instrument instead of "Lock & Block". In order to prevent this Locking bracket is attached to the top of the commutator disc, so that when the armature is attracted out of the Locking notch of the commutator disc when the door lock coil being energised, it gets into the notch of the Locking bracket and during the operation of the Commutator Handle from TOL to Line Closed ,the armature is forced dropped . In the latest instruments the notch cut on the bracket is made sloping (instead of a rectangular one), so that if the armature once electrically attracted out of the locking notch of the commutator disc and held up due to residual magnetism or a mechanical defect it shall be forced down on its holding pawl when the commutator is turned from TOL to Line Closed position, thereby avoiding a failure, which would otherwise result in suspension of Block Working. In normal working the Block Clearance circuit is so arranged that after the arrival of the train inside the Block clearance point, when the Home Signal lever is replaced to Normal, and the Bell Plunger pressed, the door lock coil is only momentarily energised, to release the locking from the commutator disc and the armature would come to rest on the holding pawl after the coil having been de-energised. Since the entire safety of Block working depends on the proper functioning of the Commutator Lock , it is vital that the functioning of Commutator Lock and Door Lock Mechanism is thoroughly checked and attended to during the periodical overhauling. It should also be 42

checked carefully and thoroughly during the periodical inspections by JE/SE/SSE of the section as ready laid down to avoid unsafe conditions. The mechanical details of the door lock mechanism shown in figure 3.11.

FIG. 3.11 SGE INSTRUMENT DOOR LOCK ARRANGEMENT The door lock coil is wound to resistance of 50 Ohms and requires a working current of 200 ma.

In S.Rly PTJ type modified Block Instrument the conditional locking on the Commutator Lock/TOL Lock is achieved by using additional Commutator Contact called TOL/LB and the associated relay eliminating the mechanical components of Door Lock Mechanism available in the other two types namely Byculla and HWH. We have seen from the circuit that the SR relay that is dropped at the sending end on entry of the train in the Block Section picks up when the commutator is turned to TOL at the receiving end. SR once picked up gets a stick feed so that a subsequent change of PR relay contact does not affect SR. For reason of safety it is essential that the commutator having been turned to TOL allowing SR to pick up at the distant end must get locked in TOL position. Vide SEM 18.16. The commutator handle is locked first 43

before the’ Train on line’ indication appears on the indication when the handle is turned from ‘ Line clear’ to ‘Train on line’ position. If the turning of commutator is done sluggishly a situation may arise in that the TOL contacts are made, but the commutator is not locked in TOL position as shown in Fig. 3.12(i).

Under this condition even though a train has occupied the Block Section the commutator can be normalised and second line clear granted which is unsafe. With the provision of Half /Auxiliary Notch as shown in Fig. 3.12(ii) in the same situation the commutator is prevented from being turned to line closed and therefore, the possibility of granting another line clear is avoided. (Refer Fig.No.3.12). 44

In lock and block the clearing of the last stop signal at a station must be dependent on the 'Line Clear' indication on the Block Instrument. As there are no relays in this instrument, a separate polar relay has to be included in series with the top indicator and the last stop signal is controlled through the same. The relay has one arm with three positions. When there is no current flowing through the relay the arm remains in the centre. With the Line Clear indication on the top indicator the direction of current through the relay is suitable to move the arm to the line clear position to complete the last stop signal control circuit. In the Train On Line (TOL) position of the indicator the direction of current is suitable to complete the circuit for a stick relay, the front contact of which is included in the last stop signal control circuit. The IRS specifications of this polarised relay is S31 / 80 and having a coil resistance of 77 Ohms, it works on a rated current of 25 mA. The following is the method of signalling a train from station A to B. A calls attention by giving one bell beat on his bell plunger, B acknowledges. 'A' then asks for line clear by sending the prescribed code of bell signals on the bell plunger. 'B' acknowledges the "Is Line Clear Signal" (if he is prepared to receive the train) by repeating the same and keeping the bell plunger pressed on the last beat of the signal (to release the mechanical lock on the commutator), turns the commutator to right from "Line Closed" position. This brings "Line Clear" Indication in B's bottom indicator and the top indicator at A. Various typical Indication circuits in Vogue are shown in figures 3.14A, 3.14B, 3.15A and 3.15B. The current now passes through the polarised relay attracts its armature to close the Last Stop Signal Circuit. Last Stop Signal is cleared.

FIG. 3.14 BLOCK BELL CIRCUIT

45

FIG. 3.14A 46

FIG. 3.14 B WIRING DIAGRAM OF (9 SEGMENT) DOUBLE LINE BLOCK INSTRUMENT IRS type E. Rly HWH make 47

Train enters section and on the actuation of the 'FVT' by the engine the LSS goes back to 'ON' automatically. 'A' gives train entering section signal on the bell plunger. 'B' acknowledges the same by repeating it and keeping the plunger pressed on the last beat, turns the commutator through 40 deg anticlockwise, from 'Line Clear' position to "Train On Line" position. Now the bottom indicator at 'B' and top indicator at 'A' register "Train On Line" indication. The circuit for this is shown in figures 3.15A and 3.15B. The commutator at ‘B’ is now locked at TOL position.

FIG. 3.15 B

INDICATION CIRCUIT

'B' takes off reception signals for the train and on its arrival inside the block clearance point (on actuation of the tracks circuit) the reception signals go back to danger and the levers are restored to Normal. The door lock coil is energised momentarily and then de-energised. This releases the lock on the commutator. 'B' turns his commutator to line closed position. Then 'B' gives the trains out of section signal which is acknowledged by 'A'.

48

Each railway adopts their own circuit for the LSS control as well as Block Release. But the basic requirements remains the same. The circuit shown in Fig. 3.17 is the one which is adopted by one of the railways. Stick relays SR1 and SR2 (QNAI type) are normally in the energised condition. The front contact of these relays are proved in the LCPR . (Line clear proving relay) pick up circuit. The important point of including the 'F' contacts of SR1, SR2 relays in the LCPR circuit is to ensure that the LSS can be taken OFF only for "One train on one line clear". When line clear is granted from Station 'B' (advanced station) by operating the commutator to line clear position the PR is operated to make “LC” contact at Station 'A' (rear station) so as to complete the LSS circuit such as +ve of battery - fuse - FVTR (F) - LSS DR(B) - LSS-L(N) - PR operated LC contact. SR1 (F) . SR2(F) - LCPR coil and to -ve. Now when the lever of LSS is reversed, through the lever (R) band the green aspect control relay of LSS - DR picks up as: +ve of battery - fuse . FVTR (F)-SM.YR(F) - SR1 (F). SR2(F) . LCPR(F)- LSSL(R) LSS. DR Coil - LSS-L.(R) and -ve of the battery. Note: (i) In this circuit the LSS.DR(B) and LSS(N) band are by passed by LCPR(F) to ensure that LCPR is held through its own front contact when the LSS is taken OFF. (ii) The LCPR(F) is by passed by DECR of LSS DG is to ensure that once the LSS is taken OFF on proper line clear it cannot be replaced to ON by any interruption to PR due to line break or mismanipulation of commutator at Station B. (iii) The (R) band of LSS - Lever is incorporated in both the +ve and -ve limbs of DR with (N) band across the relay is to effect cross protection. (iv) If QNA1 relays are used for SRs then it is essential to use 2 QNA1 relays as SR1 and SR2. The idea of this is to maintain that the pick up time of SR shall not be less than 300 ms. This time delay is necessary to ensure that the SR does not pick up (to reclear the LSS after a train admitted into the section) due to momentary swinging action of the armature of the PR and making TOL contact when the commutator of the instrument at the advanced station is accidentally or deliberately brought back to Line Closed and again operated to Line Clear Position before the arrival of the train into the station. (v) The pick up circuit of LCPR is first taken through LSS. DR(B) and LSS-L(N) to prove that line clear is received ensuring that the concerned Last Stop Signal is at "ON" while receiving line clear.

49

FIG. 3.17 LSS CONTROL CIRCUIT The commutator at the advanced station is locked in TOL position when it is brought from Line Clear and can be brought to "Line Closed" only when the commutator lock is released after arrival of the train inside the block clearance point and the reception signals have been restored back to Normal. The circuit details to achieve this condition are shown in figure 3.18A and 3.18B. Two closed track circuits (3/4) AT, (3/4) BT (not less than two rail length each) adjacent to each other are provided just in advance of the Home Signal. When the train for which line clear is given being received on proper reception signal the first track (3/4) AT having occupied by the train, the relay (3/4) ATPR drops and through the back contact of this relay the first relay of the block release circuit (UP) ZR1 picks up and stick. The circuit for this is:Battery +ve - fuse - (UP) - ZR3(B) - (3/4) ATPR(B) - (3/4)BTPR(F) - any one of the H-S lever (R) band - (UP) ZR2(B) - (UP) ZR1 relay coil and battery -ve. The stick path for this is made available through one of its own front contacts. Further when the train is on its run comes on the second track, (3/4) BT, the relay (3/4) BTR drops and on clearance of (3/4) AT the ATPR picks up. Now the second block release relay (UP) ZR2 picks up through: B +ve - fuse - (UP) ZR3(B) - (3/4) ATPR (F) - (3/4) BTPR (B) (UP) ZR1 (F) - (UP) ZR2 relay coil and -ve of the battery and sticks through one of its own front contacts. The relay (UP) ZR2 must be of slow to release feature as this is essential to pick up the final block release relay (UP) ZR3 without any interruption. The pick up circuit for this is self explanatory. The (UP) ZR3 on its picking up disconnects the feed to the other two relays (UP) ZR1 and (UP) ZR2 by opening its back contact and sticks through one of its own front contacts. 50

When the (UP) ZR2 picks up it gives an audible and visual indication to remind the SM to operate the commutator of the respective block instrument to TOL if it is not already done by him to complete the sequence of operations for the entry and arrival of the train into the station. The relay (UP) ZR3 when it picks up complete the circuit to energise the lock coil of the commutator when the plunger is pressed through the relevant normal contacts of Reception Signal’s levers and back contact of signal’s controlling and lamp checking relays so as to release the lock and restore the commutator back to "Line Closed" position. By adopting this circuit a relaxation is done to avoid block failure without jeopardising the safety facilitating the operation of commutator from line clear to TOL and back to line close even after arrival of the train into the Station. Note: i) The word Up and Dn represents for the direction of train movements. ii) The prefixed numerical No. (3/4) represents the Home Signal Number.

51

52

53

As one of the latest modifications in the system of Double Line Block working the AUTO TOL system is introduced to get a buzzer and TOL indication automatically at the train receiving station when the train enters the block section from the train sending station. In the existing SGE Double Line Block working, if the receiving end SM fails to turn the Block Handle to TOL position promptly we find a contradicting indication that the train is in the Block Section where as the Bottom indicator is indicating Line Clear. At times, due to turning the commutator inadvertently, we find another disputable condition that the train has not entered the Block Section but the indication assumes TOL which is termed as premature TOL . In such a case a Block Failure results. To obviate these difficulties it is proposed to introduce automatic train on line feature in the existing SGE Double Line Block Instruments in a phased manner. The system of such working adopted by one of the railways is shown in Fig. 3.23(b). When a train enters the block section from Station A on proper line clear the FVT track is actuated and this causes a momentary disconnection to the line circuit. This momentary disconnection to the line enable a magnetic latch relay AR (QL1) at Station 'B' to be operated. The operating circuit is as:- B +ve ZR(B) and ZR1(B) - LR(B) - LPR(F) - R1R2 of AR coil and to -ve of battery. As soon as this relay is operated, through one of the 'R' contacts of this relay the polarity of indication battery changes as +ve to earth and -ve to line duly bringing the TOL indications automatically in the respective indicators at Station B and A. In addition to this a Buzzer is also switched on at Station B automatically through one of the operated R contacts of AR. On receiving the Buzzer the SM at Station B operates the commutator of the instrument to TOL and this action not only operates the magnetic latch relay to Normal but also stop the buzzer. The commutator is now locked at TOL. Note: i) The relay LR & LPR are used to effect the condition for operation of latch relay AR (QLI). ii) The inclusion of LCZR (N) and AR(N) in the line circuit is to prove that positive operation of AR is taken place and to change the polarity of indication battery to register the appearance of TOL indication on the dials. iii) The relay LCZR is used to ensure that the sequence of operations are taken place. iv) The parallel path of LSSRP(B) to FVTR(F) is to ensure that the indication on the dial is not interrupted so long the train is on FVT. Where Station provided with Semaphore signalling and passing loops the block working will be different from others. A method adopted by one of the Railways is shown in Fig.3.20. Before giving line clear to the rear station the reception line has got to be nominated, all the points over which the incoming train will pass are correctly set and facing points locked and the nominated line must be clear up to the starter signal before section can be cleared or line clear for another train granted. In this connection detailed circuits for giving line clear, Last Stop Signal control and Block release are as shown in the Figure 3.20.

54

55

A lock with SM’s key is provided for locking the commutator block handle in all the 3 positions by the operator, the arrangement of which is given in Drg.No.3.21.

Fig. 3.21 COMMUTATOR LOCKING ARRANGEMENT Based on the recommendations of the committee appointed by the Railway Board to examine the working of the Double Line Block Instruments particularly the SGE Type which is most commonly used, the Rly. Board have issued some instructions vide their letter No.81/104/SG/G/3 dt. 30-4-85. Some important instructions are given below:1. Shelf type relays or QSPA1 type or two Nos. of QNA1 Type relays in tandem with a minimum pick up time of 300 ms should only be used in stick relay circuit SR. 2. Polarised relays conforming to IRS-S31-80 should only be used in the block circuits. However, AEI-GRS polarised relays with contact gap of 1.5 mm and minimum pick up current of 16 mA can be allowed to continue till they are progressively replaced with polarised relays conforming to IRS-S31-80. 3. 3-position polarised relays should be overhauled once in 10-12 yrs. 4. All block instruments should be manufactured only to IRS design. 56

5. All the block instruments manufactured in the Railway Workshop also should be duly inspected by RDSO. 6. Sequential clearance of two circuits should be provided for block clearance. 7. If any of the following conditions are observed, the lock and block should be treated as defective and its working suspended:i) the last stop signal is not restored to ON position automatically by the passage of the train. ii) if it is found possible to take OFF the last stop signal without containing the "Line Clear" indication on the instrument. iii) if the block instruments commutator could be turned from TOL to Line Clear position without the arrival of train. iv) when the block instrument shows erratic movements of the indicators or is defective in any other way. In order to comply the instructions vide items 1 and 6 above, a circuit diagrams adopted by one of the railways are given in Fig. 3.17, 3.18A and 3.18B. The system of Double Line Block Working adopted by RDSO/LKO is as shown in the circuit diagram No.3.23(a).

ASTR ASTPR ASSR (These Relays or normally energised when there is no train in the Block section)

I. BSR (This relay is normal energised ) Commutator is turned to Line Clear Position to grant Line Clear. LCR and sticks. Block battering connected to line and earth

II. PR (When PR is in Line Clear, the Line Clear contact LC is made)

TC KR TCKPR

LCPR ASDR (when slide is reversed) LSS is taken OFF Train enters the section ASTR is actuated ASTR ASTPR ASSR (Line circuit is opened) PR

III.

57

TCKR TCKPR BSR

(Slow to release)

TOLR and stick and now the battery polarity is connected as +ve to line and –ve to earth. TCKR TCKPR TOL indication appears instead of LCK. and TOL Buzzer sounds SM operates COMM. To TOL TOL Buzzer stops. LCR IV. PR makes its TOL contact,Line Clear indication Dissapears; TOL indication apears. ASTR ASTPR ASSR

After the train clears the AS TR V. Train is received on Home Signal. HS. ATPR Sequentially QR HS.BTPR HS.ATPR

Operated and finally QR

Operated

Sequentially HS.BTPR QR

and finally

and stick

HS. BTPR

QR

Operates train Arrival buzzer. Energises DC to release the Comm. Lock.

QR BSR TOLR TAR-ACK SM operates TAR. ACK. Button and Operates COMM. Line closed. TOLR TCKR TCKPR TOL indication disappear Line closed indication Appears. BSR and stick Train arrival buzzer stops. VI. PR TOL indication disappears; Line Closed indication appears.

58

Fig. 3.23A.

59

60

Statement showing some of the main differences between the three types of Double Line Block Instruments.

1.

2.

Contact arrangement

4 pairs of spring contact (Finger type) mounted inside the instrument, contacts are closed by brass segments when a Fan shaped ebonite piece operated by commutator Telephone and Bell Provided externally set. in separate housing.

3.

Polarised Relay.

Provided as a part of instrument externally

4.

Door Lock Mechanism arrangement SM’s Lock

Mechanical stick

Duplicate Lock arrangements Auto – TOL- Buzzer/ Indication Resistance of Door coil/TOL lock coil Working current of Door coil/TOL Lock coil Resistance of Bell Relay Working current of Bell relay Resistance of Bell Coil

5. 6. 7. 8. 9. 10. 11. 12.

Not effective on locking Bell plunger

6 way circuit controller type and the contacts are closed in a rotary form when the commutator is operated.

9 way drum type with slotted segments. Contacts are closed when split spring strips are made to move over these segments when commutator is operated. Provided Provided externally internally in one in separate housing. housing Provided as a Provided as a part part of of instrument instrument externally internally Electrical stick Mechanical stick Not effective on locking Bell plunger

Not provided

Effective on locking Bell plunger also Provided

Not provided

Provided

Not provided

50 Ohms

48 Ohms

14.8 Ohms

200 mA

250 mA

250 mA

500 Ohms

400 Ohms

400 Ohms

20 mA

25 mA

25 mA

60 Ohms

48 Ohms

30 Ohms

provided

The following is the Method of signalling a train from Station X to Station Y. X asks Y for Line Clear. Y turns the Commutator handle of his Instrument to Line Clear(green) Indication. This changes the bottom indicator of Y to Line Clear (green) indication and the top Indicator of X to Line Clear (green) Indication , At the same time. this connects the battery at Y to line and picks up the polarised relay at X so as to close the Line Clear contact of the polarised relay.

61

Through the Line Clear contact of the relay, the LSS is cleared and the train enters the block section. On getting the Train Entering section signal from station X , station Y turns the Commutator handle to TOL position, thereby changing the indications to the Train On Line (Red) at both the stations. Once station Y turns the commutator handle to TOL position, the handle gets locked In that position. The Electro- magnet controlling, this lock can be energised only after the arrival of the train which shall operate the last vehicle track circuits, Sequentially. Once the home signal is taken off at Y station the train enters the station and occupies and clears the LVT Track circuits . This occupation and clearance of the track circuits releases the TOL lock , thereby permitting the commutator handle to be turned to line Closed Position .

The Block Instruments shall be considered to have failed and block working suspended in the following circumstances -(a) When the indications on the 'Train Going To' dial at X do not correspond with the indications of the 'Train Coming From' dial at Y. (b) When ever there is reason to believe that there is contact between the Block and any other circuit. Note : If an intermittent contact exists between the block and the circuit an irregular movement of the indicator or irregular bell beats or both. will be observed. If permanent contact exists there may be a permanent wrong indication or bell beats or both. A contact between block wires might cause signals given on the instrument to be repeated on the neigh boring instrument or change of indications in the instruments. (c) When a train arrives at a station without "Line Clear". Note : In this case the irregularity shall be reported as an accident unless the Driver is in possession of an -Authority to Proceed Without Line Clear". (d) If the Block Instrument or its battery counter is found without seals or locks. (e) Whenever Single Line working is introduced. (f) When the dial indicator glass is broken. (g) If the Operating Handle can be restored from ‘Train On Line' position to 'Line Closed'’ position before complete arrival of the train. (h)Where the Operating Handle cannot be turned to 'Train On Line' or 'Line Clear' or to 'Line Closed' in the process of granting or cancelling line Clear. (i) Where signals on the bell are not received distinctly or fail' altogether. (j)When a train which has entered the block section on Line Clear" is pushed backed for any reason into the station. K) If it is known that the instrument is defective in any .way not specified above.

General requirements and special requirements of Block instruments are incorporated in SEM chapter VII – section N. Instructions for installation and maintenance of Block instruments as laid down in SEM chapter XVIII shall be followed. Maintenance schedules for Block instruments, their periodicity as prescribed in SEM Annexure 28 para 18.57 shall be followed.

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Any circuit in the vicinity of 25KV AC electrified section is likely to be influenced by Electrostatic and Electromagnetic induction. These induced voltages may cause hazardous effects on the functioning of signalling and telecom. equipment and may prove to be a source of potential danger to the maintenance and operating staff. It is, therefore, necessary that suitable protective measures are adopted to minimise the effect of induced voltage. The maximum induced voltage occurring in a conductor of lead sheathed armoured cable to I.R. specification No.E17/59 under normal conditions of 600 amps. traction current has been estimated to be 35V per KM length of cable running parallel to the track provided the cable sheathing are effectively earthed at both ends. For protection of the maintenance staff, it is necessary that the maximum induced voltage of any circuit under normal traction current (600 amps) does not exceed 120V. The length of parallelism of any circuit should, therefore, not exceed 3 Km. Unscreened armoured cable to IRS specification IRS 63/89 is used, under normal conditions (i.e) 800 Amps for Single Line and 1000 Amps for Double Line – the estimated induced voltages are 116V/KM and 95V/km respectively. Block Instruments may use special PVC insulated quads in the aluminum sheathed cable or other suitable means of communication like optic Fibre Cable, Radio etc. for their working. When quad cable is used for the working Block Instruments, Block Telephone and Block Bell circuits shall be worked through a transformer utilising the two pairs of block quad. The Block circuits shall be worked on the phantom pair or by other suitable means. Unless two circuits are physically separated, the length of parallelism is the combined length of the circuits from end to end. For example, where circuits are connected with a common battery/transformer, the length of parallelism is the combined length of the individual circuits fed from the battery/transformer as the case may be which should be reckoned for the purpose of taking the length of parallelism. As a rule, no earth return circuit shall be permitted in the vicinity of A.C. voltage induced on any electrical signalling equipment used on A.C. traction. A factor of safety of 2.5 is normally to be allowed over the calculated figures of induced voltage (35V per KM) for determining the suitability of electrical signalling equipment for A.C. traction. It is also necessary that the dielectric strength of the current carrying parts of the equipment and the body should be comparatively high. The recommended dielectric strength for existing equipment is to be of the order of 1000 volts and for new equipment 3000 volts. The following Electrical Signalling Equipments are not safe to withstand AC induced voltages. The coils of these equipment can only be used inside a cabin or a location box on internal circuits only. The coils of these equipment shall be worked from a separate battery and this battery shall not be connected to any external circuits going outside the cabin location box. a) Banner type slot indicators - Track indicators luminous indicators, telephone type relays. Electric lever locks cabin type reversers, door coil of SGE Block instrument, 250 ohms. DC neutral line relay (S2 or S4). b) Signal Arm and Light Repeater 63

c) Heppers Key Transmitters d) DC Neutral Polar Relays. :- SGE type block instrument with certain protective devices can be used for AC Traction for double line sections. Neale's type of single line block instruments can also be used with certain modifications and protective devices. Push button type Single line Tokenless Block Instruments may be used on Non-Electrified Section taking off from Electrified section if the length of parallelism does not exceed 1.5 km. No other type of block instruments e.g. sykes lock and block etc. shall be used on AC electrified sections unless prior approval of Railway Board is obtained. The following precautions shall be taken for SGE or Neale's, daido S.L. Block Instruments on AC traction:a) A filter of an approved design shall be installed between the single or double line block instrument and the line wire. The general arrangement for these filters are shown in Fig.4.8(a). It is essential that the line and block instrument terminals of the filters are never interchanged. The filter is a low pass filter consisting of series choke coils S1 and S2 in each line and the shunt condenser CI. The condensers adopted are 4-terminal condensers to prove the continuity of the conductors forming the condenser. Also two gaseous type lightning arrestors with a flash voltage of 150 volts are provided on the line side for high voltage protection. Two different Earths shall be provided for Discharger and Block. Separate Line Battery or DC-DC converter shall be used for each Block Instrument. This battery shall feed only the Block Instruments and not any other circuit.

4.8a SCHEMATIC DIAGRAM OF BLOCK FILTER UNIT b) When a block section originates at a station in electrified area and terminates at a station in non-electrified area, filters shall be provided with the block instruments at both ends of such block section in accordance with approved instructions.

64

Fig. 4.8b WIRING DIAGRAM OF BLOCK BELL EQUIPMENT

65

Fig. 4.8b SCHEMATIC DIAGRAM OF TRAIN WIRE AND BLOCK BELL EQUIPMENT (ITI MAKE) c) The 3 position polarised relay shall be installed in the same location as the block instruments. Only approved type of polarised relays (S31/80) shall be used in block instruments. The polarised relay manufactured by Eastern Railway Block Shop shall not be used on A.C. traction. d) The resistance of needle coil should be approximately 140 Ohms. The block telephone of single or double line block instruments shall not be worked on the same line wire as the block instrument. It shall be worked on a separate pair of line wires as indicated in Fig..4.8(b). The figure also indicates the arrangements for block bell working for SGE. Block instruments and train wire working. For bell code signalling 150 cycles tone is either sent or received with the B relay (SO/4) in the normal position. When 150 cycles tone is received, the same is rectified by the rectifier and the DC voltage developed across CI is utilised to energise the bell relay (line type relay) which, in turn, will energise the single stroke bell. For transmission of bell code signal the pressing of the plunger will energise B relay. B relay energising will apply D.C. supply to the 150 cycles transistor oscillator, the output of which will also be connected to the line through a variable resistance, thus sending a 150 cycles tone on line. A block telephone is connected across the line through a condenser when the B relay is normal. When the B relay picks up, the block telephone is cut off. Arrangements for Double Line Block working with block filter and special equipment for train wire and block bell are shown in Fig. 4.8a, 4.8b,

66

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Before Neale's single line token instruments can be retained on AC traction, they shall be modified. The modifications to be carried out in Neale's 'A' type token instrument, along with the arrangements for connecting a block filter are shown in Fig. 4.10 (a). In this, only one line is utilised for block instruments, and the second line is spare. The block bell circuit is as in the case of SGE block instrument. One difficulty encountered in the Neale's token instrument is that if the polarised relay PR is normally connected across the line so that when signalling the condensers of the filter get charged, and subsequently, when the signalling is stopped, the polarized relay coming across the lines, the condensers can discharge through this relay causing it to operate and thus release the block handle locks. To obviate this eventuality, 2 relays BNPR relay and BNR relay are incorporated as shown along with two 5000 Ohms. resistors. Of these, relay BNPR is made slow to release. When the plunger is pressed, the relay BNR is first energised, and subsequently, relay BNPR energizes over the front contact of BNR relay. With both BNPR and BNR relays energizing, the line is extended up to the commutator and D.C. signalling can be done. When the plunger is released, the relay BNR deenergises first but, relay BNPR does not de-energise immediately as it is slow to release (0.8 Sec). Thus, the two 5000 Ohms resistors are connected in parallel across the line through the pick up contacts of BNPR relay and the back contacts of BNR relay. This enables the filter condenser to discharge sufficiently. After this BNPR relay also releases cutting off the resistors and bringing the polarized relay between line and earth for reception of signals from other station. In AC Electrified areas identified with DC stray currents, metallic return is used. The circuit is as in Fig. 4.10b. (a) A separate battery shall be used for each block instrument. This battery shall only feed the block instruments and not any other circuits. (b) A separate battery shall be used for external circuits, i.e., for circuits going outside the cabin location box. (c) A separate battery shall be used for internal circuits inside a cabin/location box. This battery shall not be connected to any circuit going outside of the cabin location box. (d) The battery for telecom. equipment shall be separate from the signalling equipment battery.

(a) As a rule no aerial circuits shall be retained in the electrified zone. The only exception may arise in the case of block circuits coming in from a non-electrified zone. However, in each such case, it must be ensured that the block wires are terminated in a suitable lead in cable upto a distance of 50 metres from the electrified track at right angle to the track. In every such case the length of parallelism and the distance of block wires from the nearest electrified track should be checked in consultation with P&T to ensure that the maximum induced voltage will be within the (60V for 600 Amps) catenary current. (b) No earth return circuits are permitted on A.C. Traction. The only exception is in the case of block instrument circuits where an earth return has to be used. But in this case, the block instrument should be suitably protected by a Filter of an approved design. (c) The block signalling equipment to be used on A.C. Traction shall be confirmed to the types mentioned in paras 6B.4.6 to 6B.4.14 and shall be installed in accordance with the instructions contained therein. If any other type of equipment is to be retained on sections to be A.C. electrified, instructions shall be obtained from GM and CR/RE Office before such equipment can be retained on A./C. traction.

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(d) All batteries and the wiring in the equipment, location box or cabin shall be well insulated from the ground. 660 Volt grade flame-proof VIR wire to ISS 434 : 1943 or PVC insulated flame retarding 660 volt grade wire to ISS 694/1955 with corrigendum No.1 of June, 1957 shall be used for wiring of location boxes and cabins.

A separate earthing shall be provided for each Block Instrument. The resistance of earthing shall not exceed 10 Ohms. As far as practicable, the earthing should be located on soft ground far from underground armoured cables, water or gas pipes etc. The earthing conductors should generally be made of copper wire of 29 mm (19 strands of 1.4 mm diameter). In case the conductor is buried underground, it should be protected from corrosion by a suitable varnish on a length of about 30 cm from entering the ground Drg. No. TCA 565. Where more than one earthing is used, the distance between earthing pipes shall not be less than 3 meters. The conductors leading to these earthings should be electrically insulated from each other throughout and also from metallic structures connected to different earthing. Modification to Daido Tokenless Block Instrument (Later version) (Single Line) to suit 25KV Traction Area. The figure 4.16 shows the circuit arrangement as it is used in one of the Railways. One block pair of lines is used for transmission and reception of frequency modulated signal. The Phantom circuit is used for transmission and reception of bell code signals on direct current. In other words, the block bell transmission is transferred to the phantom circuit. The pair of wires used for train wire circuit remains the same. Due to the provision of filter unit on the Phantom line for the protection against induced voltage, the bell code transmission becomes sluggish and also the speech of telephone is considerably low. The arrangement is similar to working of Neale's Token Instrument in A.C. Traction Area. Two external relays BNR1 and BNPR1 are provided on the filter unit circuit to guard against picking up of 'NR' relay due to the discharge current of capacitor of FILTER UNIT. During the transmission of D.C. feed by pressing push button PB1 or PB2 both the capacitors of the filter unit are charged and when the transmission ceases the capacitor discharges but the bell code circuit becomes isolated because of BNR1 and BNPR1Relays. To guard against picking of 'NR' relay, during the discharge of the capacitor, a back contact of BNPR1 relay slow to release has been included in the 'NR' circuit. The modifications required are shown in Fig. .4.14. Further details for modifications are furnished in the Chapter S6.C.

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Block Systems working on overhead lines or underground cable are often affected with contact faults which can cause failures or unsafe conditions if extra precautions are not taken. Therefore, if Fibre Optical Cables are used between two stations for transmission of data, safety can be enhanced by interconnecting the Block Instruments in two stations by using OFC The effect of A.C. Induction due to parallelism is eliminated in OFC medium of transmission. equipment developed by M/s. NKT Electronics – NKT SA 8800 and the indigenously developed equipment of M/s. DELTRON are in use in Indian Railways. This equipment is universal in that the same assembly can be used for working different types of Block Instruments, viz., a) SGE Double Line Block Instrument, b) Neale’s Token Block Instrument and c) DAIDO Type FM Single Line Tokenless Block Instruments with minor wiring changes done locally. Two schematic diagrams for the safe-line system are given in the figures at the end of this book.

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